CN111215382A - High-efficient belt cleaning device of ferrite - Google Patents

Abstract

The invention provides a high-efficiency cleaning device for ferrite, and belongs to the technical field of machinery. The method solves the technical problems that the surface cleaning efficiency of the existing sintered ferrite is low and the like. The utility model provides a high-efficient belt cleaning device of ferrite, which comprises a frame, be fixed with the washing case that is used for storing the washing liquid in the frame, be provided with in the frame and penetrate the conveyer belt that washs the case and can submerge in the washing liquid, it shakes the board to wash the incasement and is fixed with the ultrasonic wave, it is provided with stripper plate one to wash the incasement, stripper plate two, stripper plate one, stripper plate two four can form crowded being used for making the ferrite stack orderly regular district, it drives stripper plate one to wash the incasement, stripper plate two removes extruded actuating mechanism. The method has the advantage of high cleaning efficiency of the surface of the sintered ferrite.

Description

High-efficient belt cleaning device of ferrite

Technical Field

The invention belongs to the technical field of machinery, and particularly relates to a high-efficiency cleaning device for ferrite.

Background

Ferrite is a metal oxide having ferrimagnetism. In terms of electrical properties, ferrites have a much higher resistivity than elemental metal or alloy magnetic materials, and also have higher dielectric properties. The magnetic properties of ferrites are also characterized by a high permeability at high frequencies. Therefore, ferrite has become a non-metallic magnetic material with wide application in the high-frequency weak-current field.

The charger adopts the E-type ferrite core, the center column of the E-type ferrite core needs to be polished according to the requirements of different customers, but before the ferrite core needs to be sintered, the pickaxe powder used for ferrite sintering separation needs to be removed, the mixing of the pickaxe powder and the ferrite powder is avoided, the influence on the later polishing is reduced, during the ferrite sintering, the stacked ferrite core is adopted to be placed on a sintering plate, each layer of ferrite is separated in the traditional cleaning mode, then the ultrasonic cleaning is carried out independently, the ferrite core needs to be separated manually, and the efficiency is low.

Disclosure of Invention

The invention aims to solve the problems in the prior art, provides a high-efficiency cleaning device for ferrite, and solves the problem of low cleaning efficiency of the surface of the ferrite after sintering.

The purpose of the invention can be realized by the following technical scheme:

a high-efficiency ferrite cleaning device comprises a rack, wherein a cleaning box used for storing cleaning liquid is fixed on the rack, a conveying belt penetrating into the cleaning box and capable of being immersed in the cleaning liquid is arranged on the rack, and an ultrasonic vibration plate is fixed in the cleaning box, and the device is characterized in that a first extrusion plate, a second extrusion plate, a first separation plate and a second separation plate are arranged in the cleaning box, the first extrusion plate, the second extrusion plate, the first separation plate and the second separation plate can form a regular area for extruding and stacking ferrites in order, a driving mechanism for driving the first extrusion plate and the second extrusion plate to move and extrude is arranged in the cleaning box, a driving mechanism for driving the first separation plate and the second separation plate to move and extrude and separate is further arranged in the cleaning box, the first separation plate comprises a plurality of first separation strips, the second separation plate comprises a plurality of second separation strips, a plurality of flat strip-shaped probes I are equidistantly fixed on the first separating strip, a plurality of flat strip-shaped probes II are equidistantly fixed on the second separating plate, the first probes and the second probes are oppositely arranged, a first connecting structure enabling the first separating strips to be equidistant is arranged between the adjacent first separating strips, a second connecting structure enabling the second separating strips to be equidistant is arranged between the adjacent second separating strips, the separation strip I is provided with a third extrusion plate used for extruding ferrite, the separation strip II is provided with a fourth extrusion plate used for extruding ferrite, the third extrusion plate and the fourth extrusion plate are respectively connected with the first separation strip and the second separation strip through elastic adjusting rods, the third extrusion plate and the fourth extrusion plate can be abutted against the first separation strip and the second separation strip after extrusion is received, the third extrusion plate is provided with a first through hole corresponding to the first probe, and the fourth extrusion plate is provided with a second through hole corresponding to the second probe.

The working principle of the invention is as follows: the sintered ferrite is communicated with the sintered bottom edges of the ferrite and is placed on a conveying belt, the ferrite is conveyed into a cleaning box through the conveying belt, the positions of the ferrite are adjusted and arranged through a first extrusion plate, a second extrusion plate, a third extrusion plate and a fourth extrusion plate, the ferrite is stacked in order, a first probe and a second probe on a first separation plate and a second separation plate penetrate into a gap between the ferrites, a driving mechanism is started after the first probe and the second probe are in butt joint, the first separation strip and the second separation strip are separated, a gap is formed between every two layers of ferrites, the ultrasonic vibration plate is started at the moment, powder between the ferrites is removed, the first probe and the second probe are reset through the driving mechanism, the first probe and the second probe are withdrawn from the gap, and the ferrite is conveyed out of the cleaning box.

In the invention, the ferrite is automatically separated, so that powder among the ferrites is conveniently cleaned, the original steps of manual separation are reduced, and the cleaning efficiency is greatly improved.

In the ferrite high-efficiency cleaning device, the driving mechanism comprises a push rod motor I, a push rod motor II, a moving frame I, a moving frame II, a driving motor and a screw rod with two sections of opposite threads, the screw is rotationally arranged in the cleaning box, the driving motor is fixed in the cleaning box, the output shaft of the driving motor is connected with the screw in a transmission way, the first moving frame and the second moving frame are arranged on the screw rod, the upper ends of the first moving frame and the second moving frame are connected with the top of the cleaning box in a sliding way, the first push rod motor is fixed on the first moving frame, the second push rod motor is fixed on the second moving frame, the first extrusion plate is fixed on a push rod of the first push rod motor, the second extrusion plate is fixed on a push rod of the second push rod motor, the movable frame I is provided with a first extrusion wheel used for abutting against the first extrusion plate, and the movable frame II is provided with a second extrusion wheel used for abutting against the second extrusion plate.

The driving motor drives the screw rod to rotate, the screw rod drives the first movable frame and the second movable frame to be close to or far away from each other, the first movable frame, the first extrusion plate on the second movable frame and the second extrusion plate are close to each other to extrude the ferrite, or the second extrusion plate is far away from to relieve the extrusion, the first adjustable extrusion plate of the first push rod motor and the second adjustable extrusion plate of the second push rod motor are convenient to extrude the ferrite, the first extrusion plate and the second extrusion plate are respectively abutted to the first extrusion wheel and the second extrusion plate through the first extrusion wheel, and the extrusion plates are prevented from being inclined.

In the ferrite high-efficiency cleaning device, the driving mechanism comprises a third push rod motor, a fourth push rod motor, a third moving frame, a fourth moving frame, a plurality of first sliding rails and a plurality of second sliding rails, the third push rod motor and the fourth push rod motor are fixed on the side wall of the cleaning box, the third push rod motor and the fourth push rod motor are oppositely arranged, the third moving frame is fixed on a push rod of the third push rod motor, the fourth moving frame is fixed on a push rod of the fourth push rod motor, the first sliding rail is fixed on the third moving frame, the second sliding rail is fixed on the fourth moving frame, a first sliding groove corresponding to the first sliding rail is formed on the first separating strip, a second sliding groove corresponding to the second sliding rail is formed on the second separating strip, the first separating strip is slidably arranged on the first sliding rail and can slide, a fifth push rod motor is fixed on the third moving frame, the push rod of the push rod motor five is connected with the separation strip I at the uppermost end, the push rod motor six is fixed on the moving frame four, the push rod of the push rod motor six is connected with the separation strip II at the uppermost end, the separation strip I at the lowermost end is fixed on the moving frame three, and the separation strip II at the lowermost end is fixed on the moving frame four.

The third push rod motor and the fourth push rod motor can drive the third movable frame and the fourth movable frame to be close to or far away from each other, the third extrusion plate and the fourth extrusion plate can extrude and press the ferrite when the third movable frame and the fourth movable frame are close to each other, then under the continuous pushing of the third push rod motor and the fourth push rod motor, the first separation strip and the second separation strip are penetrated into a gap between the ferrites, and then the first separation strip and the second separation strip are driven to move upwards in two directions through the fifth push rod motor and the sixth push rod motor. The adjacent first separation strips are separated, the second separation strips are separated, and the ferrite is convenient to clean.

In the high-efficient belt cleaning device of above-mentioned ferrite, connection structure one include a plurality of spliced poles one, separation strip one lower extreme seted up slide opening one, spliced pole one penetrate in the slide opening one, spliced pole one be connected with a slide opening bottom through extension spring one, spliced pole one on seted up spacing groove one, separation strip one on be fixed with spacing piece one, spacing piece card is gone into in the spacing groove one. When the first adjacent separating strips are not separated, the first connecting column penetrates into the first sliding block, the first adjacent separating strips are in contact with each other, and when the first uppermost separating strip is pulled upwards, the first connecting column enables the distances between the first adjacent separating strips to be equal. When the uppermost separating strip I is reset, the adjacent separating strips I are abutted again under the action of the tension spring I and gravity.

In the high-efficient belt cleaning device of above-mentioned ferrite, connection structure two include a plurality of spliced poles two, two lower extremes of separation strip seted up slide opening two, spliced pole two penetrate in the slide opening two, spliced pole two be connected with two bottoms in the slide opening through extension spring two, spliced pole two on seted up spacing groove two, separation strip two on be fixed with spacing piece two, spacing piece two card is gone into in the spacing groove two. When the two adjacent separating strips are not separated, the two connecting columns penetrate into the two sliding blocks, the two adjacent separating strips are in contact with each other, and when the two separating strips at the uppermost end are pulled upwards, the distance between the two adjacent separating strips is equal through the two connecting columns. When the second separation strip at the uppermost end is reset, the second adjacent separation strips are abutted again under the action of gravity through the second tension spring.

In the ferrite high-efficiency cleaning device, the upper surfaces of the first probe and the second probe are smooth planes. The first probe and the second probe can penetrate between the ferrites conveniently, and the first probe and the second probe can be prevented from being scratched by the ferrites.

In the ferrite high-efficiency cleaning device, a first magnet is fixed at one end of the probe, a second magnet is fixed at the two ends of the probe, and the first magnet can attract the second magnet. The bending of the first probe and the second probe after weighing is prevented.

Compared with the prior art, the invention has the following advantages:

1. in the invention, the ferrite is automatically separated, so that powder among the ferrites is conveniently cleaned, the original steps of manual separation are reduced, and the cleaning efficiency is greatly improved.

2. The ferrite position can be adjusted through the first extrusion plate, the second extrusion plate, the third extrusion plate and the fourth extrusion plate, and the first probe and the second probe can penetrate conveniently.

3. The first probes and the second probes are in one-to-one correspondence, and can be mutually attracted and fixed after being contacted, so that the weighing capacity of the ferrite can be improved, and the ferrite can be orderly arranged when the first probes and the second probes separate or reset.

Drawings

FIG. 1 is a schematic of the present invention.

Fig. 2 is a test cross-sectional view of the present invention.

FIG. 3 is a schematic view of the first and second separation plates of the present invention.

Fig. 4 is a partial sectional view of the first separator plate and the second separator plate according to the present invention.

In the figure, 1, a frame; 2. a cleaning tank; 3. a conveyor belt; 4. an ultrasonic vibration plate; 5. a first extrusion plate; 6. a second extrusion plate; 7. a first separating plate; 7a, a first separating strip; 7a1, a first slide hole; 8. a second separation plate; 8a, a second separating strip; 8a1 and a sliding hole II; 9. a first probe; 10. a second probe; 11. a third extrusion plate; 12. a fourth extrusion plate; 13. a push rod motor I; 14. a push rod motor II; 15. a first movable frame; 16. a second moving frame; 17. a drive motor; 18. a screw; 19. a first extrusion wheel; 20. a second extrusion wheel; 21. a third push rod motor; 22. a push rod motor IV; 23. a third movable frame; 24. a fourth moving frame; 25. a first slide rail; 26. a second slide rail; 27. a push rod motor V; 28. a push rod motor six; 29. connecting a column I; 29a, a first limit groove; 30. a first tension spring; 31. a first limiting block; 32. connecting a second column; 32a and a second limiting groove; 33. a tension spring II; 34. a second limiting block; 35. a magnet I; 36. and a second magnet.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

As shown in fig. 1 to 4, a high-efficiency cleaning device for ferrite comprises a frame 1, a cleaning tank 2 for storing cleaning liquid is fixed on the frame 1, a conveying belt 3 which penetrates into the cleaning tank 2 and can be immersed in the cleaning liquid is arranged on the frame 1, an ultrasonic vibration plate 4 is fixed in the cleaning tank 2, a first extrusion plate 5, a second extrusion plate 6, a first separation plate 7 and a second separation plate 8 are arranged in the cleaning tank 2, the first extrusion plate 5, the second extrusion plate 6, the first separation plate 7 and the second separation plate 8 can form a regular area for stacking the ferrite, a driving mechanism for driving the first extrusion plate 5 and the second extrusion plate 6 to move and extrude is arranged in the cleaning tank 2, a driving mechanism for driving the first separation plate 7 and the second separation plate 8 to move and extrude and separate is also arranged in the cleaning tank 2, the first separation plate 7 comprises a plurality of first separation strips 7a, the second separation plate 8 comprises a plurality of second separation strips 8a, a plurality of flat strip-shaped probes 9 are equidistantly fixed on the first separating strip 7a, a plurality of flat strip-shaped probes 10 are equidistantly fixed on the second separating plate 8, the probes 9 are opposite to the probes 10, a first connecting structure for enabling the first separating strip 7a to be equidistant is arranged between the adjacent first separating strips 7a, a second connecting structure for enabling the second separating strips 8a to be equidistant is arranged between the adjacent second separating strips 8a, a third extrusion plate 11 for extruding ferrite is arranged on the first separating strip 7a, a fourth extrusion plate 12 for extruding ferrite is arranged on the second separating strip 8a, the third extrusion plate 11 and the fourth extrusion plate 12 are respectively connected with the first separating strip 7a and the second separating strip 8a through elastic adjusting rods, the third extrusion plate 11 and the fourth extrusion plate 12 can be abutted against the first separating strip 7a and the second separating strip 8a after extrusion is received, a first through hole corresponding to the first probe 9 is arranged on the third extrusion plate 11, the fourth extrusion plate 12 is provided with a second through hole corresponding to the second probe 10.

The working principle of the invention is as follows: the sintered ferrite is communicated with and placed on the bottom edge of the sintered ferrite and is placed on a conveying belt 3 together, the ferrite is conveyed into a cleaning box 2 through the conveying belt 3, then the ferrite is adjusted and arranged in order through a first extrusion plate 5, a second extrusion plate 6, a third extrusion plate 11 and a fourth extrusion plate 12, the ferrite is stacked in order, then a first probe 9 and a second probe 10 on a first separation plate 7 and a second separation plate 8 penetrate into a gap between the ferrites, after the first probe 9 and the second probe 10 are in butt joint, a driving mechanism is started to separate the first separation strip 7a and the second separation strip 8a, a gap is generated between each layer of ferrite, at the moment, an ultrasonic vibration plate 4 is started to remove powder between the ferrites, the driving mechanism enables the first probe 9 and the second probe 10 to reset, enables the first probe 9 and the second probe 10 to exit from the gap, and the ferrite is conveyed out of the cleaning box 2.

In the invention, the ferrite is automatically separated, so that powder among the ferrites is conveniently cleaned, the original steps of manual separation are reduced, and the cleaning efficiency is greatly improved.

Specifically, the driving mechanism comprises a first push rod motor 13, a second push rod motor 14, a first moving frame 15 and a second moving frame 16, the cleaning device comprises a driving motor 17 and a screw rod 18 with two sections of opposite threads, wherein the screw rod 18 is rotatably arranged in a cleaning box 2, the driving motor 17 is fixed in the cleaning box 2, an output shaft of the driving motor 17 is in transmission connection with the screw rod 18, a first moving frame 15 and a second moving frame 16 are arranged on the screw rod 18, the first moving frame 15 and the second moving frame 16 are connected with the top of the cleaning box 2 in a sliding manner, a first push rod motor 13 is fixed on the first moving frame 15, a second push rod motor 14 is fixed on the second moving frame 16, a first extrusion plate 5 is fixed on a push rod of the first push rod motor 13, a second extrusion plate 6 is fixed on a push rod of the second push rod motor 14, a first extrusion wheel 19 used for abutting against the first extrusion plate 5 is arranged on the first moving frame 15, and a second extrusion wheel 20 used for abutting against the.

The driving motor 17 drives the screw rod 18 to rotate, the screw rod 18 drives the first movable frame 15 and the second movable frame 16 to be close to or far away from each other, the first movable frame 15, the first extrusion plate 5 on the second movable frame 16 and the second extrusion plate 6 are close to each other to extrude the ferrite, or the first movable frame 18 is far away from and removed from extrusion, the first adjustable extrusion plate 5 of the first push rod motor 13 and the second adjustable extrusion plate 5 of the second push rod motor 14 are used for conveniently extruding the ferrite, the first extrusion plate 5 and the second extrusion plate 6 are respectively abutted through the first extrusion wheel 19 and the second extrusion wheel 20, and the deflection of the extrusion plates is prevented.

Specifically, the driving mechanism comprises a third push rod motor 21, a fourth push rod motor 22, a third moving frame 23, a fourth moving frame 24, a first slide rail 25 and a second slide rail 26, the third push rod motor 21 and the fourth push rod motor 22 are fixed on the side wall of the cleaning box 2, the third push rod motor 21 and the fourth push rod motor 22 are arranged oppositely, the third moving frame 23 is fixed on a push rod of the third push rod motor 21, the fourth moving frame 24 is fixed on a push rod of the fourth push rod motor 22, the first slide rail 25 is fixed on the third moving frame 23, the second slide rail 26 is fixed on the fourth moving frame 24, a first slide groove 7a corresponding to the first slide rail 25 is arranged on the first separating bar 8a, a second slide groove corresponding to the second slide rail 26 is arranged on the second separating bar 8a, the first separating bar 7a is arranged on the first slide rail 25 in a sliding manner and can slide, the second separating bar 8a is arranged on the second slide rail 26 in a sliding manner and can slide, the push rod of the push rod motor five 27 is connected with the separation strip one 7a at the uppermost end, the push rod motor six 28 is fixed on the moving frame four 24, the push rod of the push rod motor six 28 is connected with the separation strip two 8a at the uppermost end, the separation strip one 7a at the lowermost end is fixed on the moving frame three 23, and the separation strip two at the lowermost end is fixed on the moving frame four 24.

The third push rod motor 21 and the fourth push rod motor 22 can drive the third moving frame 23 and the fourth moving frame 24 to approach or separate from each other, the third extrusion plate 11 and the fourth extrusion plate 12 can extrude the ferrite when the third moving frame 23 and the fourth moving frame 24 approach, then under the continuous pushing of the third push rod motor 21 and the fourth push rod motor 22, the first separation strip 7a, the first probe 9 and the second probe 10 on the separation strip penetrate into a gap between the ferrites, and then the first separation strip 7a and the second separation strip 8a are driven to move upwards through the fifth push rod motor 27 and the sixth push rod motor 28. The adjacent first separation strips 7a are separated, and the second separation strips 8a are separated, so that the ferrite is convenient to clean.

Specifically, the first connecting structure comprises a plurality of first connecting columns 29, the lower ends of the first separating strips 7a are provided with first sliding holes 7a1, the first connecting columns 29 penetrate into the first sliding holes 7a1, the first connecting columns 29 are connected with the bottoms of the first sliding holes 7a1 through first tension springs 30, the first connecting columns 29 are provided with first limiting grooves 29a, the first separating strips 7a are fixed with first limiting blocks 31, and the first limiting blocks 31 are clamped into the first limiting grooves 29 a. When the adjacent separation strips 7a are not separated, the connecting posts 29 penetrate into the sliding blocks I, the adjacent separation strips 7a are contacted, and when the uppermost separation strip 7a is pulled upwards, the distances between the adjacent separation strips 7a are equal through the connecting posts 29. When the uppermost separating strip I7 a is reset, the adjacent separating strips I7 a are abutted again under the action of gravity through the tension springs I30. The connecting column one 29 is fixed on the separating strip one 7 a.

Specifically, the second connecting structure comprises a plurality of second connecting columns 32, the lower ends of the second separating columns 8a are provided with second sliding holes 8a1, the second connecting columns 32 penetrate into the second sliding holes 8a1, the second connecting columns 32 are connected with the bottoms of the second sliding holes 8a1 through second tension springs 33, the second connecting columns 32 are provided with second limiting grooves 32a, the second separating columns 8a are fixed with second limiting blocks 34, and the second limiting blocks 34 are clamped into the second limiting grooves 32 a. When the two adjacent separating strips 8a are not separated, the two connecting columns 32 penetrate into the two sliders, the two adjacent separating strips 8a are in contact with each other, and when the two uppermost separating strips 8a are pulled upwards, the two connecting columns 32 enable the distances between the two adjacent separating strips 8a to be equal. When the second separating strip 8a at the uppermost end is reset, the second separating strips 8a adjacent to each other are abutted again under the action of gravity through the second tension spring 33. The second connecting column 32 is fixed on the second separating strip 8 a.

Specifically, the upper surfaces of the first probe 9 and the second probe 10 are smooth planes. The first probe 9 and the second probe 10 can penetrate between the ferrites conveniently, and the first probe 9 and the second probe 10 can be prevented from scratching the ferrites.

Specifically, a first magnet 35 is fixed at the end of the first probe 9, a second magnet 36 is fixed at the end of the second probe 10, and the first magnet 35 can attract the second magnet 36. And the first probe 9 and the second probe 10 are prevented from bending after being weighed.

The above components are all standard components or components known to those skilled in the art, and the structure and principle thereof can be known to those skilled in the art through technical manuals or through routine experiments.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the spirit or ambit of the invention as defined in the appended claims.

Claims (7)

1. A high-efficiency ferrite cleaning device comprises a rack, wherein a cleaning box used for storing cleaning liquid is fixed on the rack, a conveying belt penetrating into the cleaning box and capable of being immersed in the cleaning liquid is arranged on the rack, and an ultrasonic vibration plate is fixed in the cleaning box, and the device is characterized in that a first extrusion plate, a second extrusion plate, a first separation plate and a second separation plate are arranged in the cleaning box, the first extrusion plate, the second extrusion plate, the first separation plate and the second separation plate can form a regular area for extruding and stacking ferrites in order, a driving mechanism for driving the first extrusion plate and the second extrusion plate to move and extrude is arranged in the cleaning box, a driving mechanism for driving the first separation plate and the second separation plate to move and extrude and separate is further arranged in the cleaning box, the first separation plate comprises a plurality of first separation strips, the second separation plate comprises a plurality of second separation strips, a plurality of flat strip-shaped probes I are equidistantly fixed on the first separating strip, a plurality of flat strip-shaped probes II are equidistantly fixed on the second separating plate, the first probes and the second probes are oppositely arranged, a first connecting structure enabling the first separating strips to be equidistant is arranged between the adjacent first separating strips, a second connecting structure enabling the second separating strips to be equidistant is arranged between the adjacent second separating strips, the separation strip I is provided with a third extrusion plate used for extruding ferrite, the separation strip II is provided with a fourth extrusion plate used for extruding ferrite, the third extrusion plate and the fourth extrusion plate are respectively connected with the first separation strip and the second separation strip through elastic adjusting rods, the third extrusion plate and the fourth extrusion plate can be abutted against the first separation strip and the second separation strip after extrusion is received, the third extrusion plate is provided with a first through hole corresponding to the first probe, and the fourth extrusion plate is provided with a second through hole corresponding to the second probe.

2. The ferrite efficient cleaning device according to claim 1, wherein the driving mechanism comprises a first push rod motor, a second push rod motor, a first moving frame, a second moving frame, a driving motor and a screw rod with two sections of opposite threads, the screw rod is rotatably arranged in the cleaning box, the driving motor is fixed in the cleaning box, an output shaft of the driving motor is in transmission connection with the screw rod, the first moving frame and the second moving frame are arranged on the screw rod, the upper ends of the first moving frame and the second moving frame are in sliding connection with the top of the cleaning box, the first push rod motor is fixed on the first moving frame, the second push rod motor is fixed on the second moving frame, the first extrusion plate is fixed on a push rod of the first push rod motor, the second extrusion plate is fixed on a push rod of the second push rod motor, the first moving frame is provided with a first extrusion wheel for abutting against the first extrusion plate, and a second extrusion wheel used for abutting against the second extrusion plate is arranged on the second movable frame.

3. The ferrite efficient cleaning device according to claim 1, wherein the driving mechanism comprises a third push rod motor, a fourth push rod motor, a third moving frame, a fourth moving frame, a first sliding rail and a second sliding rail, the third push rod motor and the fourth push rod motor are fixed on the side wall of the cleaning tank, the third push rod motor and the fourth push rod motor are oppositely arranged, the third moving frame is fixed on the push rod of the third push rod motor, the fourth moving frame is fixed on the push rod of the fourth push rod motor, the first sliding rail is fixed on the third moving frame, the second sliding rail is fixed on the fourth moving frame, the first separating bar is provided with a first sliding groove corresponding to the first sliding rail, the second separating bar is provided with a second sliding groove corresponding to the second sliding rail, the first separating bar is slidably arranged on the first sliding rail and can slide, the second separating bar is slidably arranged on the second sliding rail and can slide, a fifth push rod motor is fixed on the third moving frame, a push rod of the fifth push rod motor is connected with the first separating strip at the uppermost end, a sixth push rod motor is fixed on the fourth moving frame, a push rod of the sixth push rod motor is connected with the second separating strip at the uppermost end, the first separating strip at the lowermost end is fixed on the third moving frame, and the second separating strip at the lowermost end is fixed on the fourth moving frame.

4. The efficient ferrite cleaning device as claimed in claim 1, wherein the first connecting structure comprises a plurality of first connecting posts, a first slide hole is formed in a lower end of the first separating bar, the first connecting posts penetrate into the first slide hole, the first connecting posts are connected with the bottoms of the first slide holes through first tension springs, first limiting grooves are formed in the first connecting posts, first limiting blocks are fixed on the first separating bars, and the first limiting blocks are clamped into the first limiting grooves.

5. The efficient ferrite cleaning device according to claim 1, wherein the second connecting structure comprises a plurality of second connecting posts, a second sliding hole is formed in the lower end of the second separating bar, the second connecting posts penetrate into the second sliding hole, the second connecting posts are connected with the bottoms of the second sliding holes through second tension springs, second limiting grooves are formed in the second connecting posts, second limiting blocks are fixed on the second separating bar, and the second limiting blocks are clamped into the second limiting grooves.

6. The efficient ferrite cleaning device as claimed in claim 1, wherein the upper surfaces of the first probe and the second probe are smooth planes.

7. The ferrite cleaning device according to claim 1, wherein a first magnet is fixed to the end of the probe, a second magnet is fixed to the end of the probe, and the first magnet can attract the second magnet.

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